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This book explores various approaches to building a positive interdisciplinary STEAM (science, technology, engineering, arts and math) learning environment, as described by educators across the K-20 educational ladder. Crucial to their success, Martinez finds, is the playful and performatory approach they employ in their teaching. Their practices are creative, improvisational, and inclusive, and are shared in detail through illustrations and interviews. Throughout the book, the author explores a Vygotskian cultural performatory approach to creating interdisciplinary STEAM learning environments, drawing out the history of this approach and its success in fostering collaboration, creativity, leadership, and communication skills, as well as its effect on social, emotional, and cognitive growth in both formal and informal educational settings.
Create meaningful and transformative K-5 STEAM learning experiences for each and every student Make the most of your limited instructional time and become part of the Step into STEAM movement! Seamlessly design and implement K-5 STEAM inquiries that align carefully to key mathematics and science content and practices and prepare elementary students for their bright futures. Taking an opposite approach to existing resources that provide collections of disjointed STEAM activities, this book empowers teachers and schools to build cohesive and sustainable STEAM infrastructures—grounded in grade-level standards and purposeful assessment—to deepen the mathematics and science learning of each and every student.
Curriculums for STEM education programs have been successfully implemented into numerous school systems for many years. Recently, the integration of arts education into such programs has proven to be significantly beneficial to students, resulting in a new method of teaching including science, technology, engineering, art, and mathematics. Cases on STEAM Education in Practice is an essential research publication for the latest scholarly information on curriculum development, instructional design, and educational benefits of STEAM learning initiatives. Featuring coverage on a range of topics including fine arts, differentiated instruction, and student engagement, this book is ideally designed for academicians, researchers, and professionals seeking current research on the implementation of STEAM education.
This book examines the push and pull of factors contributing to and constraining conversion of STEM (science, technology, engineering and math) education programs into STEAM (science, technology, engineering, math and arts) education programs. The chapters in this book offer thought-provoking examples, theory, and suggestions about the advantages, methods and challenges involved in making STEM to STEAM conversions, at levels ranging from K12 through graduate university programs. A large driving force for STEM-to-STEAM conversions is the emerging awareness that the scientific workforce finds itself less than ideally prepared when engaging with so-called ‘wicked problems’ – the complex suite of emerging, multifaceted issues such as global climate change, social injustice, and pandemic diseases. Dealing with these issues requires cross-disciplinary expertise and the ability to insert technical and scientific understanding effectively into areas of public planning and policy. The different models and possibilities for STEAM, as the next phase of the STEM revolution, laid out in this book will promote research and further our understanding of STEAM as a forward-thinking approach to education. Gillian Roehrig, STEM Education, University of Minnesota, USA The ideal teacher sees opportunities for integrating ideas from multiple disciplines into every lesson. This book offers many worthwhile suggestions on how to do that deliberately and systematically George DeBoer, Project 2061 of the American Association for the Advancement of Science, USA For the last several years, calls for expanding STEM education have grown, but so too have concerns about technocratic approaches to STEM. This volume challenges the community to consider broader views on STEM by focusing on the place of arts education within this movement. The chapters offer much needed, new perspectives on the (re)integration of the arts and sciences Troy Sadler, School of Education, University of North Carolina, USA
The addition of the arts to STEM education, now known as STEAM, adds a new dimension to problem-solving within those fields, offering students tools such as imagination and resourcefulness to incorporate into their designs. However, the shift from STEM to STEAM has changed what it means for students to learn within and across these disciplines. Redesigning curricula to include the arts is the next step in preparing students throughout all levels of education. Challenges and Opportunities for Transforming From STEM to STEAM Education is a pivotal reference source that examines the challenges and opportunities presented in redesigning STEM education to include creativity, innovation, and design from the arts including new approaches to STEAM and their practical applications in the classroom. While highlighting topics including curriculum design, teacher preparation, and PreK-20 education, this book is ideally designed for teachers, curriculum developers, instructional designers, deans, museum educators, policymakers, administrators, researchers, academicians, and students.
This book looks at the value of integrating the arts and sciences in the school curriculum. It argues that this will help students further their understanding of analytical concepts through the use of creativity. The authors illustrate how schools can work towards presenting common practices, concepts, and content. Coverage features case studies and lessons learned from classrooms across the United States. The notion of STEAM (Science, Technology, Engineering, Arts, and Mathematics) is an emerging discipline unique in its desire to provide a well-rounded approach to education. The chapters of this volume examine STEAM in a variety of settings, from kindergarten to higher education. Readers will learn about the practical considerations involved when introducing the arts and creativity into traditionally left brain processes. This includes best practices for creating and sustaining successful STEAM initiatives in any school, college, or university. For instance, one chapter discusses novel approaches to teach writing with the scientific method in order to help students better present their ideas. The authors also detail how the arts can engage more diverse learners, including students who are not traditionally interested in STEM subjects. They provide three concrete examples of classroom-tested inquiries: designing a prosthetic arm for a child, making a paleontology investigation, and taking a closer look at the arts within roller coaster engineering. This book is an invaluable resource for teachers and teacher trainers, university faculty, researchers, and school administrators. It will also be of interest to science, mathematics, engineering, computer science, information technology, arts and design and technology teachers.
Modern society gives great importance to scientific and technological literacy, development of “21st century skills,” and creating individuals who are not passive users of ICT tools but active thinkers and even tinkerers. The learning process is thus constantly evolving to facilitate the acquisition of such skills, such as setting goals and making evidence-based decisions, thinking critically, and solving problems while efficiently managing time as well as using technology, cooperating ethically, and communicating effectively. STEAM is the approach to learning that uses concepts from natural sciences, technology, engineering, arts, and mathematics to foster critical thinking, computational and design thinking, as well working effectively together, mimicking the process followed by scientists. The end goal is engaged and motivated students who participate in experiential and inquiry-based learning in fun, immersive environments that facilitate learning through a creative process. The Handbook of Research on Integrating ICTs in STEAM Education includes current research focusing on the development of STEAM and ICT educational practices, tools, workflows, and frames of operation that encourage science skills, but also skills related to the arts and humanities such as creativity, imagination, and reflection on ethical implications. Covering topics such as early childhood education, machine learning education, educational robotics, and web-based simulations, this major reference work is an essential resource for engineers, educators of both K-12 and higher education, education administration, libraries, pre-service teachers, computer scientists, researchers, and academics.
This practical book will help readers understand what STEAM is, how it differs from STEM, and how it can be used to engage students in K–8 classrooms. The authors present a conceptual model with recommendations and classroom examples illustrating various key aspects of STEAM teaching in action, including creating the correct teaching environment, integrating STEAM content, and supporting students as they develop STEAM-related skills. The model includes specific strategies such as problem-based learning, student choice, technology integration, and teacher facilitation. Each chapter incorporates elements of connected learning—a type of learning that draws on students’ interests that teachers can capitalize on when using STEAM to address real-world problems.Readers will find easy-to-understand examples of what STEAM education looks like in a variety of classrooms, and will hear from teachers, instructional coaches, principals, and administrators about what it takes to ensure that STEAM is a schoolwide success. “Provides inspiration to sustain readers through this challenging work by emphasizing the rewards for both students and educators who engage in STEAM education.” —From the Foreword by Deborah Hanuscin, Western Washington University “This text will be appreciated by school and district staff interested in implementing STEAM education for students.” —Kevin O’Gorman, chief academic officer, Berkeley County School District, SC “This book will become a go-to for crafting meaningful STEAM learning experiences for students.” —Nicole Beeman-Cadwallader, National Math and Science Initiative
A comprehensive guide to service-learning for social justice written by an international panel of experts The Wiley International Handbook of Service-Learning for Social Justice offers a review of recent trends in social justice that have been, until recently, marginalized in the field of service-learning. The authors offer a guide for establishing and nurturing social justice in a variety of service-learning programs, and show that incorporating the principles of social justice in service-learning can empower communities to resist and disrupt oppressive power structures, and work for solidarity with host and partner communities. With contributions from an international panel of experts, the Handbook contains a critique of the field’s roots in charity; a review of the problematization of Whitenormativity, paired with the bolstering of diverse voices and perspectives; and information on the embrace of emotional elements including tension, ambiguity, and discomfort. This important resource: Considers the role of the community in service-learning and other community‐engaged models of education and practice Explores the necessity of disruption and dissonance in service-learning Discusses a number of targeted issues that often arise in service-learning contexts Offers a practical guide to establishing and nurturing social justice at the heart of an international service-learning program Written for advanced undergraduate students, graduate students, scholars, and educators, The Wiley International Handbook of Service-Learning for Social Justice highlights social justice as a conflict‐ridden struggle against inequality, xenophobia, and oppression, and offers practical suggestions for incorporating service-learning programs in various arenas.
STEAM education can be described in two ways. One model emphasizes the arts and is not as concerned about the accuracy of the STEM fields. In the second model, STEM content is the prevailing force with a focus on accuracy, and the arts are used in limited and secondary resources for the teaching of the content. However, in order to promote creative thinking, allow for higher student engagement, and offer a more well-rounded education, a STEAM model, where science, technology, engineering, arts, and mathematics are equal contributors to the process of learning, is needed. Cases on Models and Methods for STEAM Education is an important scholarly resource that provides inclusive models and case studies highlighting best techniques and practices for implementing STEAM models in teaching and assists teachers as they learn to use such methods through the inclusion of practical activities for use in the classroom. Highlighting a wide range of topics such as science education, fine arts, and teaching models, this book is essential for educators, administrators, curriculum developers, instructional designers, policymakers, academicians, researchers, and students.